The system relies on the ability of high intensity lasers to set up a thin plasma sheet (or a hot sheet) in the atmosphere that depends on the beam intensity and geometry. The laser beam can be spread and directed with physical optics to generate a thin hot shell (micrometer scale) conical shape waveguide in the atmosphere. The hot shell of the waveguide will have a different index of refraction (n) from that of the surrounding air layers and as such will serve to internally reflect (redirect) portions of the entering sun rays toward the base of the cone thus resulting in a virtual solar energy concentration system. As the solar energy descends through the aperture, the energy density quickly multiplies. At the base of the aperture, a massive amount of energy now exist that can be collected and converted.

A large scale replacement of a conventional solar energy harnessing system. As the solar energy descends through the aperture, the energy density quickly multiplies. At the base of the aperture, a massive amount of energy now exists that can be collected and converted.

The technology may be deployed in such a manner as to significantly reduce the global warning effect without adverse effects.

Advantages

Novel solar concentrator that could increase the magnification of the solar energy over ten thousand times, while not requiring a large physical structure typically associated with traditional optics.

The plasma field would generate a virtual waveguide, with no mechanical structure, to focus the incoming solar energy to a small collection point. This would enable a more efficient and economical system to be developed to convert the solar energy into electrical energy.